Comparing Two Methods of Surface Change Detection on an Evolving Thermokarst Using High-Temporal-Frequency Terrestrial Laser Scanning, Selawik River, Alaska

Terrestrial laser scanners (TLS) allow large and complex landforms to be rapidly surveyed at previously unattainable point densities. Many change detection methods have been employed to make use of these rich data sets, including cloud to mesh (C2M) comparisons and Multiscale Model to Model Cloud Comparison (M3C2). Rather than use simulated point cloud data, we utilized a 58 scan TLS survey data set of the Selawik retrogressive thaw slump (RTS) to compare C2M and M3C2. The Selawik RTS is a rapidly evolving permafrost degradation feature in northwest Alaska that presents challenging survey conditions and a unique opportunity to compare change detection methods in a difficult surveying environment. Additionally, this study considers several error analysis techniques, investigates the spatial variability of topographic change across the feature and explores visualization techniques that enable the analysis of this spatiotemporal data set. C2M reports a higher magnitude of topographic change over short periods of time ( 12 h) and reports a lower magnitude of topographic change over long periods of time ( four weeks) when compared to M3C2. We found that M3C2 provides a better accounting of the sources of uncertainty in TLS change detection than C2M, because it considers the uncertainty due to surface roughness and scan registration. We also found that localized areas of the RTS do not always approximate the overall retreat of the feature and show considerable spatial variability during inclement weather; however, when averaged together, the spatial subsets approximate the retreat of the entire feature. New data visualization techniques are explored to leverage temporally and spatially continuous data sets. Spatially binning the data into vertical strips

[1]  D. Lague,et al.  Accurate 3D comparison of complex topography with terrestrial laser scanner: Application to the Rangitikei canyon (N-Z) , 2013, 1302.1183.

[2]  Michel Jaboyedoff,et al.  Detection of millimetric deformation using a terrestrial laser scanner: experiment and application to a rockfall event , 2009 .

[3]  S. Lane,et al.  Estimation of erosion and deposition volumes in a large, gravel‐bed, braided river using synoptic remote sensing , 2003 .

[4]  Giuseppe Casula,et al.  Remote Sensing and Geodetic Measurements for Volcanic Slope Monitoring: Surface Variations Measured at Northern Flank of La Fossa Cone (Vulcano Island, Italy) , 2013, Remote. Sens..

[5]  Gérard G. Medioni,et al.  Object modeling by registration of multiple range images , 1991, Proceedings. 1991 IEEE International Conference on Robotics and Automation.

[6]  Andreas Kääb,et al.  Flow field of Kronebreen, Svalbard, using repeated Landsat 7 and ASTER data , 2005, Annals of Glaciology.

[7]  Garnett P. Williams,et al.  The case of the shrinking channels; the North Platte and Platte rivers in Nebraska , 1978 .

[8]  Gérard G. Medioni,et al.  Object modelling by registration of multiple range images , 1992, Image Vis. Comput..

[9]  J. Brasington,et al.  Accounting for uncertainty in DEMs from repeat topographic surveys: improved sediment budgets , 2009 .

[10]  A. Lewkowicz,et al.  Nature and Importance of Thermokarst Processes, Sand Hills Moraine, Banks Island, Canada , 1987 .

[11]  E O Hovey,et al.  THE GEOLOGICAL SOCIETY OF AMERICA. , 1902, Science.

[12]  J. Nichol,et al.  Satellite remote sensing for detailed landslide inventories using change detection and image fusion , 2005 .

[13]  T. Hamilton,et al.  Late Cenozoic glaciation of Alaska , 1994 .

[14]  Konrad A Hughen,et al.  Arctic Environmental Change of the Last Four Centuries , 1997 .

[15]  Rebecca Hodge,et al.  Using simulated terrestrial laser scanning to analyse errors in high-resolution scan data of irregular surfaces , 2010 .

[16]  Paul R. Bierman,et al.  Old images record landscape change through time , 2005 .

[17]  Piotr Zagórski,et al.  Use of terrestrial laser scanning (TLS) for monitoring and modelling of geomorphic processes and phenomena at a small and medium spatial scale in Polar environment (Scott River — Spitsbergen) , 2014 .

[18]  Martin Charlton,et al.  Application of airborne LiDAR in river environments: the River Coquet, Northumberland, UK , 2003 .

[19]  James H. Foster,et al.  Compact Multipurpose Mobile Laser Scanning System - Initial Tests and Results , 2013, Remote. Sens..

[20]  D. Girardeau-Montaut,et al.  CHANGE DETECTION ON POINTS CLOUD DATA ACQUIRED W ITH A GROUND LASER SCANNER , 2005 .

[21]  A. Abellán,et al.  Detection and spatial prediction of rockfalls by means of terrestrial laser scanner monitoring , 2010 .

[22]  E. S. Melnikov,et al.  Circum-Arctic map of permafrost and ground-ice conditions , 1997 .

[23]  A. Lewkowicz,et al.  Use of an ablatometer to measure short-term ablation of exposed ground ice , 1985 .

[24]  Michael N. Gooseff,et al.  Effects of Hillslope Thermokarst in Northern Alaska , 2009 .

[25]  Wade L. Nutter,et al.  CHANNEL MORPHOLOGY EVOLUTION AND OVERBANK FLOW IN THE GEORGIA PIEDMONT 1 , 1999 .

[26]  Alexander L. Densmore,et al.  Detection of surface change in complex topography using terrestrial laser scanning: application to the Illgraben debris‐flow channel , 2011 .

[27]  C. White Repeat Photography: Methods and Applications in the Natural Sciences , 2012 .

[28]  J. Brasington,et al.  Methodological sensitivity of morphometric estimates of coarse fluvial sediment transport , 2003 .

[29]  P. Friele,et al.  Geomorphology, Vegetation Succession, Soil Characteristics and Permafrost in Retrogressive Thaw Slumps near Mayo, Yukon Territory , 1989 .

[30]  G. Heritage,et al.  Towards a protocol for laser scanning in fluvial geomorphology , 2007 .

[31]  D. Petley,et al.  Terrestrial laser scanning for monitoring the process of hard rock coastal cliff erosion , 2005, Quarterly Journal of Engineering Geology and Hydrogeology.

[32]  S. Hagemann,et al.  Vulnerability of Permafrost Carbon to Climate Change: Implications for the Global Carbon Cycle , 2008 .

[33]  C. Symon,et al.  Arctic climate impact assessment , 2005 .

[34]  Derek D. Lichti,et al.  APPLICATION OF A HIGH-RESOLUTION, GROUND-BASED LASER SCANNER FOR DEFORMATION MEASUREMENTS , 2001 .

[35]  Rolf Aalto,et al.  Channel and Floodplain Change Analysis over a 100-Year Period: Lower Yuba River, California , 2010, Remote. Sens..

[36]  Juha Hyyppä,et al.  Mapping Topography Changes and Elevation Accuracies Using a Mobile Laser Scanner , 2011, Remote. Sens..

[37]  Falko Kuester,et al.  Terrestrial Laser Scanning-Based Structural Damage Assessment , 2010, J. Comput. Civ. Eng..

[38]  Robert E. Kayen,et al.  Topographic Change Detection at Select Archeological Sites in Grand Canyon National Park, Arizona, 2006-2007 , 2009 .

[39]  M. Sturm,et al.  The evidence for shrub expansion in Northern Alaska and the Pan‐Arctic , 2006 .

[40]  K. Roberts,et al.  Thesis , 2002 .

[41]  M. Crosetto,et al.  Deformation measurement using terrestrial laser scanning data and least squares 3D surface matching , 2008 .

[42]  Trevor C. Lantz,et al.  Increasing rates of retrogressive thaw slump activity in the Mackenzie Delta region, N.W.T., Canada , 2008 .

[43]  Dimitri Lague,et al.  3D Terrestrial LiDAR data classification of complex natural scenes using a multi-scale dimensionality criterion: applications in geomorphology , 2011, ArXiv.

[44]  Jan Nyssen,et al.  Linking long-term gully and river channel dynamics to environmental change using repeat photography (Northern Ethiopia) , 2011 .

[45]  N. Matsuoka,et al.  Monitoring periglacial processes: Towards construction of a global network , 2006 .